Susanne X Wang1, Larry Arsenault, Ernst B Hunziker. 1. Center of Regenerative Medicine for Skeletal Tissues, Department of Clinical Research, University of Bern, CH-3010 Bern, Switzerland.
Abstract
BACKGROUND: Two strains of guinea pig develop spontaneous osteoarthritis of the knee. Although the disease evolves at different rates in the two strains, it is not known whether these differences are reflected in the structure of the cartilage and cancellous bone. QUESTIONS/PURPOSES: We determined whether the three-dimensional structure of the tibial-plateau cartilage and femoral cancellous bone differed between the two strains. METHODS: Six Dunkin-Hartley and six GOHI/SPF guinea pigs were evaluated. The animals were sacrificed at 11 months of age. The 24 proximal tibias were used for a stereologic histomorphometric analysis of the tibial-plateau cartilage. The 24 femurs were used for a site-specific, three-dimensional quantitative analysis of the cancellous bone by micro-CT. RESULTS: Compared to the GOHI/SPF guinea pigs, the tibial-plateau cartilage of the Dunkin-Hartley strain had a larger lesion volume (3.8% versus 1.5%) and a thicker uncalcified cartilage layer (0.042 versus 0.035 mm), but a thinner calcified cartilage zone (0.008 versus 0.01 mm) and a thinner subchondral cortical bone plate (0.035 versus 0.039 mm). The femoral cancellous bone in the Dunkin-Hartley strain had a lower bone mineral density (477 versus 509 mg/cm(3)). However, the trabeculae were thicker (3.91 versus 3.53 pixels) and farther apart (7.8 versus 5.6 pixels). The osteoarthritic changes in the cartilage were topographically mirrored in the subchondral bone. They were most severe on the medial side of the joint, particularly in the anterior region. CONCLUSIONS: Spontaneous osteoarthritis in the guinea pig is associated with site-specific changes in the articular cartilage layer, which are topographically mirrored in the underlying subchondral bone. CLINICAL RELEVANCE: Three-dimensional structural information not revealed by two-dimensional radiography may help characterize the stages of osteoarthritis.
BACKGROUND: Two strains of guinea pig develop spontaneous osteoarthritis of the knee. Although the disease evolves at different rates in the two strains, it is not known whether these differences are reflected in the structure of the cartilage and cancellous bone. QUESTIONS/PURPOSES: We determined whether the three-dimensional structure of the tibial-plateau cartilage and femoral cancellous bone differed between the two strains. METHODS: Six Dunkin-Hartley and six GOHI/SPF guinea pigs were evaluated. The animals were sacrificed at 11 months of age. The 24 proximal tibias were used for a stereologic histomorphometric analysis of the tibial-plateau cartilage. The 24 femurs were used for a site-specific, three-dimensional quantitative analysis of the cancellous bone by micro-CT. RESULTS: Compared to the GOHI/SPF guinea pigs, the tibial-plateau cartilage of the Dunkin-Hartley strain had a larger lesion volume (3.8% versus 1.5%) and a thicker uncalcified cartilage layer (0.042 versus 0.035 mm), but a thinner calcified cartilage zone (0.008 versus 0.01 mm) and a thinner subchondral cortical bone plate (0.035 versus 0.039 mm). The femoral cancellous bone in the Dunkin-Hartley strain had a lower bone mineral density (477 versus 509 mg/cm(3)). However, the trabeculae were thicker (3.91 versus 3.53 pixels) and farther apart (7.8 versus 5.6 pixels). The osteoarthritic changes in the cartilage were topographically mirrored in the subchondral bone. They were most severe on the medial side of the joint, particularly in the anterior region. CONCLUSIONS: Spontaneous osteoarthritis in the guinea pig is associated with site-specific changes in the articular cartilage layer, which are topographically mirrored in the underlying subchondral bone. CLINICAL RELEVANCE: Three-dimensional structural information not revealed by two-dimensional radiography may help characterize the stages of osteoarthritis.
Authors: R D Kapadia; A M Badger; J M Levin; B Swift; A Bhattacharyya; R A Dodds; R W Coatney; M W Lark Journal: Osteoarthritis Cartilage Date: 2000-09 Impact factor: 6.576
Authors: Janet M Anderson-MacKenzie; Helen L Quasnichka; Roger L Starr; E Jonathan Lewis; Michael E J Billingham; Allen J Bailey Journal: Int J Biochem Cell Biol Date: 2005-01 Impact factor: 5.085
Authors: M A Karsdal; D J Leeming; E B Dam; K Henriksen; P Alexandersen; P Pastoureau; R D Altman; C Christiansen Journal: Osteoarthritis Cartilage Date: 2008-03-24 Impact factor: 6.576
Authors: Lauren B Radakovich; Angela J Marolf; John P Shannon; Stephen C Pannone; Vanessa D Sherk; Kelly S Santangelo Journal: Connect Tissue Res Date: 2017-12-11 Impact factor: 3.417
Authors: Virginia Byers Kraus; Sheng Feng; ShengChu Wang; Scott White; Maureen Ainslie; Marie-Pierre Hellio Le Graverand; Alan Brett; Felix Eckstein; David J Hunter; Nancy E Lane; Mihra S Taljanovic; Thomas Schnitzer; H Cecil Charles Journal: Arthritis Rheum Date: 2013-07
Authors: Zaitunnatakhin Zamli; Kate Robson Brown; John F Tarlton; Mike A Adams; Georgina E Torlot; Charlie Cartwright; William A Cook; Kristiina Vassilevskaja; Mohammed Sharif Journal: Biomed Res Int Date: 2014-06-18 Impact factor: 3.411
Authors: Silvia Fernández-Martín; Antonio González-Cantalapiedra; María Permuy; Mario García-González; Mónica López-Peña; Fernando Muñoz Journal: Front Vet Sci Date: 2021-04-22
Authors: Andrew J Teichtahl; Anita E Wluka; Pushpika Wijethilake; Yuanyuan Wang; Ali Ghasem-Zadeh; Flavia M Cicuttini Journal: Arthritis Res Ther Date: 2015-09-01 Impact factor: 5.156
Authors: Naga Padmini Karamchedu; Josef N Tofte; Kimberly A Waller; Ling X Zhang; Tarpit K Patel; Gregory D Jay Journal: Arthritis Res Ther Date: 2016-03-14 Impact factor: 5.156